Hybrid Nanocomposites : Fundamentals, Synthesis, and Applications / edited by Kaushik Pal.
Material type:
TextPublisher: Singapore : Pan Stanford Publishing, 2019Description: 1 online resourceContent type: text Media type: computer Carrier type: online resourceISBN: 9780429000966; 0429000960; 9780429671159; 0429671156; 9780429672644; 0429672640; 9780429669668; 0429669666Subject(s): Nanocomposites (Materials) | Nanostructured materials industry -- Technological innovations | TECHNOLOGY & ENGINEERING / Engineering (General) | TECHNOLOGY & ENGINEERING / Reference | TECHNOLOGY / Material Science | TECHNOLOGY / NanotechnologyDDC classification: 620.1/15 LOC classification: TA418.9.N35Online resources: Taylor & Francis | OCLC metadata license agreement Cover; Half Title; Title Page; Copyright Page; Table of Contents; Preface; 1: Graphene-Based Polymer Nanocomposites for Sensor Applications; 1.1 Introduction; 1.2 Graphene-Based Polymer Nanocomposites; 1.3 Synthesis of Graphene-Assembled Polymer Nanocomposites; 1.3.1 Solution Blending; 1.3.2 Melt Blending; 1.3.3 In situ Polymerization; 1.4 Varieties of Graphene-Based Polymer Nanocomposites; 1.4.1 Graphene/Polyaniline Nanocomposites; 1.4.2 Graphene/Poly(3,4-Ethylene Dioxythiophene); 1.4.3 Graphene/Epoxy Nanocomposites; 1.4.4 Graphene/Polystyrene Nanocomposites
1.4.5 Graphene/Polyurethane Nanocomposites1.4.6 Graphene/Poly(Vinyl Alcohol) Nanocomposites; 1.4.7 Graphene/Polyethylene Terephthalate Nanocomposites; 1.4.8 Graphene/Polycarbonate Nanocomposites; 1.4.9 Graphene/Poly(Vinylidene Fluoride) Nanocomposites; 1.4.10 Graphene/Nafion Nanocomposites; 1.4.11 Graphene/Carbon Nanotube-Polymer Nanocomposites; 1.4.12 Typical Graphene-Based Polymer Composites; 1.5 Applications of Graphene-Based Polymer Composites; 1.5.1 Sensors Applications; 1.5.2 Gas Sensors; 1.5.3 Applications of Biosensors, Optical Sensors, and Calorimetric Sensors
1.6 Conclusions, Outlook, and Future Scope2: Facile Synthesis and Applications of Polyaniline/TiO2 Hybrid Nanocomposites; 2.1 Introduction; 2.1.1 Conducting Polymers; 2.1.2 Nanocomposites of Conducting Polymers; 2.1.2.1 Building block approach; 2.1.2.2 In situ approach; 2.1.3 Polyaniline; 2.1.3.1 Structure of polyaniline; 2.1.3.2 Synthesis of polyaniline; 2.1.4 Titanium Dioxide; 2.1.4.1 Structure of TiO2; 2.2 PANI/TiO2 Hybrid Nanocomposites; 2.2.1 Different Structures of PANI/TiO2 Hybrid Nanocomposites; 2.2.2 Synthesis of PANI/TiO2 Hybrid Nanocomposites; 2.2.2.1 Chemical methods
2.2.2.2 In situ polymerization2.2.2.3 The electrochemical method; 2.2.2.4 Enzymatic synthesis; 2.2.2.5 The self-assembly method; 2.2.2.6 Template polymerization; 2.2.2.7 Gamma irradiation; 2.2.2.8 The microemulsion method; 2.2.2.9 The inverse emulsion method; 2.2.2.10 One-pot polymerization; 2.2.3 Effect of Surfactants; 2.3 Properties of Hybrid Composites; 2.3.1 Optical/Photocatalytic Properties; 2.3.2 Electrical/Dielectric Properties; 2.4 Applications of PANI/TiO2 Composites; 2.4.1 Photocatalysis; 2.4.2 Smart Corrosion-Resistant Coatings; 2.4.3 Sensors; 2.4.4 Energy Storage Devices
2.4.5 Fuel Cells2.4.6 Dye-Sensitized Solar Cells; 2.5 Conclusion; 3: Metal Oxide Nanocomposites: Cytotoxicity and Targeted Drug Delivery Applications; 3.1 Introduction; 3.2 Metal Oxide Nanocomposites and Their Types; 3.2.1 Magnetic Nanocomposites; 3.2.1.1 Iron oxide-metal nanocomposites; 3.2.1.2 Iron oxide-carbon allotrope nanocomposites; 3.2.1.3 Iron oxide-polymer nanocomposites; 3.2.1.4 Novel magnetic nanocomposites; 3.2.2 Nonmagnetic Nanocomposites; 3.2.2.1 Metal-metal oxide nanocomposites; 3.2.2.2 Metal oxide-carbon a llotrope nanocomposites; 3.2.2.3 Metal oxide-polymer nanocomposites
Understanding surfaces and interfaces is a key challenge for those working on hybrid nanomaterials and where new imaging and analysis spectroscopy/electron microscopy responses are vital. The variability and site recognition of biopolymers, such as DNA molecules, offer a wide range of opportunities for the self-organization of wire nanostructures into much more complex patterns, while the combination of 1D nanostructures consisting of biopolymers and inorganic compounds opens up a number of scientific and technological opportunities. This book discusses the novel synthesis of nanomaterials and their hybrid composites; nanobiocomposites; transition metal oxide nanocomposites; spectroscopic and electron microscopic studies; social, ethical, and regulatory implications of various aspects of nanotechnology; and significant foreseeable applications of some key hybrid nanomaterials. The book also looks at how technology might be used in the future, estimating, where possible, the likely timescales in which the most far-reaching applications of technology might become a reality. Current research trends and potential future advances, such as nanomaterials, nanometrology, electronics, optoelectronics, and nanobiotechnology, are discussed, in addition to the benefits they are currently providing in the short, medium, and long terms. Furthermore, the book explains the current and possible future industrial applications of nanotechnology, examines some of the barriers to its adoption by industry, and identifies what environmental, health and safety, ethical, or societal implications or uncertainties may arise from the use of the technology, both current and future.
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